Abstract
Autophagy and epithelial to mesenchymal transition (EMT) are major biological processes in cancer. Autophagy is a catabolic pathway that aids cancer cells to overcome intracellular or environmental stress, including nutrient deprivation, hypoxia and drugs effect. EMT is a complex transdifferentiation through which cancer cells acquire mesenchymal features, including motility and metastatic potential. Recent observations indicate that these two processes are linked in a complex relationship. On the one side, cells that underwent EMT require autophagy activation to survive during the metastatic spreading. On the other side, autophagy, acting as oncosuppressive signal, tends to inhibit the early phases of metastasization, contrasting the activation of the EMT mainly by selectively destabilizing crucial mediators of this process. Currently, still limited information is available regarding the molecular hubs at the interplay between autophagy and EMT. However, a growing number of evidence points to the functional interaction between cytoskeleton and mitochondria as one of the crucial regulatory center at the crossroad between these two biological processes. Cytoskeleton and mitochondria are linked in a tight functional relationship. Controlling mitochondria dynamics, the cytoskeleton cooperates to dictate mitochondria availability for the cell. Vice versa, the number and structure of mitochondria, which are primarily affected by autophagy-related processes, define the energy supply that cancer cells use to reorganize the cytoskeleton and to sustain cell movement during EMT. In this review, we aim to revise the evidence on the functional crosstalk between autophagy and EMT in cancer and to summarize the data supporting a parallel regulation of these two processes through shared signaling pathways. Furthermore, we intend to highlight the relevance of cytoskeleton and mitochondria in mediating the interaction between autophagy and EMT in cancer.
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Facts
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Autophagy and EMT are two major processes in cancer.
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Autophagy plays oncosuppressive function but also serves tumor cells as a strategy to overcome stressful conditions.
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EMT is associated with increased autophagy that helps cells to survive stressful environmental and intrinsic conditions.
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Major signaling pathways including TGFβ converge on the regulation of autophagy and EMT.
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The reciprocal interaction between cytoskeleton and mitochondria serves as the functional hub in the interplay between autophagy and EMT in cancer.
Open questions
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Which are the molecular mediators that link autophagy and EMT in cancer?
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Which is the role of structural proteins (including Cadherins and Integrins) in controlling autophagy in response to EMT activation in tumor cells?
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How mitochondria dynamics affects cellular architecture during EMT and metastatic spreading?
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How the interplay between autophagy and EMT influences cancer development and progression?
Cancer progression can be regarded as a multistep evolutionary process through which cancer cells acquire competences to survive in severely unfavorable microenvironmental conditions. At each step of progression, cancer cells acquire new abilities to overcome physiological barriers restraining growth. This adaptation process involves alteration of cellular functions and implies cooperation among distinct cellular pathways.1
Autophagy is a catabolic process that mediates degradation of unnecessary or dysfunctional cellular components2, 3 (Figure 1). Through this mechanism cells eliminate damaged (and potentially dangerous) molecules or organelles, thus ensuring maintenance of cellular homeostasis. However, autophagy is also used as a cellular strategy to overcome intracellular or environmental stress, including nutrient deprivation, hypoxia and drugs effect.4, 5, 6 Degradation of cellular components may be an alternative mechanism to provide energy supplies and basic metabolites to cells.
This dual function makes autophagy a ‘Janus-faced’ player in cancer progression. On the one side autophagy plays cancer-suppressive functions by eliminating potentially harmful components; on the other side it helps cells to overcome the stressful conditions that they undergo during cancer progression.7
The epithelial to mesenchymal transition (EMT) is a biological process that allows epithelial cells to transiently assume mesenchymal features by undergoing profound molecular and biochemical changes8 (Figure 2). As a consequence of this process, epithelial cells shed their differentiated characteristics, including cell–cell adhesion, polarity and lack of motility to acquire more immature features, including high cellular plasticity, motility, invasiveness and resistance to apoptosis.8, 9, 10, 11 The EMT process and its reverse, the mesenchymal–epithelial transition, are leading mechanisms during embryonic development, when the correct equilibrium between these phenomena regulates the morphogenesis of organs and tissues.12 EMT is also the leading biological process of metastasis during cancer progression since it confers to cancer cells the ability to move from the original site to colonize adjacent or distant sites.10, 11, 12, 13, 14 Even though this process requires a precise regulation of gene expression and activation of specific signaling pathways, EMT is mainly determined by the morphological reprogramming of cellular architecture, which is guided by changes in the interaction properties of the cells with the surrounding microenvironment and is supported by a profound reorganization of the cell cytoskeleton.15, 16, 17, 18
Autophagy and EMT have been regarded for long time as too distant to be connected. However, recent observations indicate that these two important processes in cancer are linked in an intricate relationship. In this review we aim to revise the evidence of a possible interplay between autophagy and EMT in cancer.
Evidence of Autophagy and EMT Functional Interaction
Several works reported a direct effect of autophagy on EMT regulation in cancer cells. In accordance with its dual role in cancer, the effect of autophagy on EMT appears controversial and likely dependent on the cellular type and/or on stage of tumor progression.
For its effect of improving resistance to unfavorable conditions, autophagy represents a powerful survival strategy for cells that are exposed to cell-intrinsic or environmental stressful stimuli. Indeed, several works show that defects in the autophagic machinery restrain dissemination and metastatic spreading of cancer.19, 20, 21, 22, 23 During metastatic spreading reorganization of the interaction properties and loss of the adhesion with the extracellular matrix leave cells without an effective anchorage and induce the activation of cell death pathways. The execution of the EMT program concurs to these massive cellular changes, promoting the exposure of cancer cells to potent demise stimuli. Autophagy induces resistance to cell death, providing a survival strategy for cells that are spreading outside the tumor mass. Fung and colleagues show that RNA interference-mediated suppression of ATG factors inhibits detachment-induced autophagy and enhances apoptosis in non-tumoral and primary mammary epithelial cells. The same authors also demonstrate that stable silencing of ATG5 or ATG7 enhances apoptosis and inhibits luminal colonization in a 3D culture model of MCF-10A breast cancer cells.24 Autophagy activation is also a general mechanism that cancer cells use to overcome the potential stress induced by hyper-activated tyrosine kinases in the absence of their key adaptor proteins tethering partners.25, 26 Sandilans and colleagues show that perturbations of the Integrin signaling through the FAK/Src axis, lead to the selective targeting of hyper-activated Src to autophagy degradation. Activation of autophagy is required for survival and protects cells toward the potential damages induced by uncontrolled Src activity.
In accordance with these observations, it has been recently reported that induction of autophagy is required for pulmonary metastasization of hepatocellullar carcinoma (HCC) cells. Stable silencing of the autophagic factors BECLIN1 (BCN1) and ATG5 in HCC cells impairs incidence of pulmonary metastases in an orthotopic mouse model. Autophagy inhibition does not affect migration or invasiveness capacity of HCC cells but reduces cell death resistance and lung tissue colonization.27 Also, N-myc downstream regulated 1 (NDRG1), known for its role of metastasis suppressor, has been shown to inhibit stress-induced autophagic responses, suggesting that its anti-metastatic activity could rely on its ability to prevent pro-survival autophagy activation in cancer cells.28
Since EMT promotes tumor metastasis and autophagy supports cell viability during the metastatic spreading, it is not surprising that EMT may promote autophagy in cancer cells. Autophagy is also a strategy used by cancer cells to promote immune surveillance escape and resistance to cytotoxic T-lymphocytes. Akalay and colleagues showed that acquisition of the EMT phenotype in MCF7 breast cancer cells is associated with attenuation in the formation of CTL-mediated immunologic synapse, increased autophagy and resistance to immune cells. Silencing of BCN1 and inhibition of the autophagic machinery restore susceptibility to T-cell cytotoxicity, suggesting that autophagy has a relevant function in helping EMT cancer cells to overcome the hostility of immune system during spreading.29
Resistance to apoptosis induced by changes in extracellular adhesion properties and the escape of the immune surveillance are major events for successful tumor metastatic spreading.
While EMT requires autophagy to support viability of potentially metastatic cancer cells, a number of additional evidence indicates that autophagy acts to prevent EMT and that the activation of the autophagic machinery may determine reversion of the EMT phenotype in cancer cells.30, 31, 32, 33, 34 It has been shown that induction of autophagy by nutrient deprivation or mTOR pathway inhibition leads to reduced migration and invasion in glioblastoma cells,33 while autophagy impairment determined by silencing of ATG5, ATG7 or BCN1 results in an increment of cell motility and invasiveness. Activation of the autophagic process leads to reduced stability and consequent downregulation of SNAIL and SLUG, two of the major transcription factors of the EMT process. This change in the transcriptional program determines re-expression of adhesion molecules and reversion of the EMT phenotype. Cadherin 6 (CDH6), a TGFβ-target gene in the EMT process, is a major switch of the transition from the epithelial to the mesenchymal phenotype and a marker of metastatic potential in thyroid cancer. We recently identified GABARAP as the interactor of the cytoplasmic domain of CDH6. We showed that CDH6 silencing reverts the EMT phenotype by reducing proliferation and migration of thyroid cancer cells. The effect of CDH6 silencing is accompanied by induction of autophagy and alteration of mitochondrial dynamics.34
The death effector domain-containing DNA-binding protein (DEDD) is a key molecule for cell death signaling receptors. Lv and colleagues recently reported that the expression of DEDD attenuates EMT, acting as the tumor suppressor signal. These authors showed that DEDD physically interacts with the autophagic controlling complex PI3K/BCN1, leading to the autophagy-mediated lysosomal degradation of SNAIL and TWIST and consequentially to the attenuation of the EMT phenotype.30 An indirect evidence of the negative crosstalk between autophagy and EMT is represented by the observation that several anticancer compounds induce autophagy while inhibiting EMT in cancer cells.35, 36, 37
Selective degradation of specific EMT proteins seems to be the major molecular mechanism through which autophagy controls EMT. TWIST1 is a helix–loop–helix transcription factor that together with SNAIL and SLUG dictates activation of EMT.38, 39 Autophagy deficiency in squamous cell carcinoma (SCC) and melanoma results in stabilization and upregulation of TWIST1, which, in turn, induces the activation of EMT in vitro and promotes tumor growth and metastasization in mice.31 TWIST1 stabilization in autophagy-deficient cancer cells is mediated by the accumulation of sequestome-1 (SQSTM1/p62), an ubiquitin-binding protein which is a target of cargo-selective autophagy. SQSTM1/p62 binds to TWIST1 and prevents its degradation through either proteasome or autophagosome. As well in non-tumoral and cancer epithelial cells TGFβ or other EMT inducing growth factors induce accumulation of SQSTM1/p62 that in turns stabilizes the TFGβ effector SMAD4 and TWIST1 leading to changes in the expression pattern of junctional proteins.40 In another work, Grassi et al.41 using liver specific autophagy-deficient mice (Alb-Cre;ATG7fl/fl), show that autophagy degrades SNAIL in a p62/SQSTM1-dependent manner, restraining EMT and migration in hepatocytes.
The negative effect of autophagy on the acquisition of the EMT phenotype is also supported by the observation that lysosomal dysfunction leads to enhanced EMT. Lysosomal dysfunction induced by V-ATPase inhibition in podocytes causes deficiency of the autophagic flux and results in decreased expression of epithelial markers (like P-Cadherin and ZO1) and increased expression of mesenchymal proteins (including FSP-1 and a-SMA). Also in this case, SQSTM1/p62 seems to be the functional link between EMT and autophagy since its accumulation due to autophagy inhibition is functional for the acquisition of the EMT phenotype.32
Taken together these observations define a complex web of interactions between autophagy and EMT. On the one side, cells that underwent EMT require autophagy activation to survive during the metastatic spreading. On the other side autophagy, acting as oncosuppressive signal, tends to inhibit the early phases of metastasization, contrasting the activation of the EMT mainly by selectively destabilizing crucial mediators of this process.
Shared Signaling Pathways and Molecular Mediators
Autophagy and EMT are both complex biological processes whose activation is tuned by an intricate web of molecular signals. Thus, it is not surprising that autophagy and EMT share common molecular mediators. The signaling pathways that regulate autophagy and those that control EMT have been extensively described in other reviews.42, 43, 44, 45, 46, 47 In this section we intend to summarize some of the evidence supporting a common regulation of these two processes (Figures 3 and 4).
TGFβ
TGFβ is a multifunctional cytokine engaged in the regulation of multiple cellular functions.48 TGFβ signaling generally plays oncosuppressive functions, repressing cell growth and inducing apoptosis. The inactivation of this pathway has been extensively linked to tumorigenesis. On the contrary, TGFβ is known to be the most powerful activator of EMT during tumor progression (Figure 3). A TGFβ ligand initiates signaling by binding to and bringing together type I and type II serine/threonine kinases receptor on the cell surface. This allows receptor II to phosphorylate the receptor I kinase domain, which then propagates the signal within the cells. The most relevant targets of TGFβ receptors are the SMAD proteins. Once activated, SMAD proteins form heteromeric complexes that are translocated into the nucleus and, in conjunction with other nuclear cofactors, regulate the transcription of target genes.48 During EMT, TGFβ signaling activates the expression of a panel of transcription factors like SNAIL, SLUG and TWIST1, which in turn orchestrate the Cadherin switch responsible for the changes in the adhesion properties of the EMT cells. We have already discussed how the destabilization of these TGFβ-upregulated transcription factors is a mechanism by which autophagy reverts the EMT phenotype in cancer cells. Besides SMAD activation, TGFβ signal is transduced within the cells through the activation of other non-canonical pathways. The p38/JNK, the PI3K/AKT/mTOR and MAPK signaling cascade are all activated by TGFβ and somehow involved in the complex regulation of EMT.
Autophagy seems to be among the wide plethora of cellular processes under TGFβ regulation. Several evidence indicates that TGFβ activates autophagy in both normal and cancer cells.49, 50, 51, 52, 53 Kiyono et al.49 showed that TGFβ treatment of HuH7 hepatocellular carcinoma cell line resulted in an early and strong activation of autophagy marked by the increased expression of pro-autophagic genes (BCN1, ATG5 and ATG7), the conversion of LC3 and the accumulation of autophagosomes. This TGFβ effect is only in part mediated by the activation of the SMAD proteins and significantly relies on the activation of p38/JNK pathway. Indeed, silencing of JNK or its chemical inhibition attenuates the TGFβ-mediated induction of autophagy and a failure of TGFβ to induce the expression of ATG5. The activation of autophagy anticipates and is required for the TGFβ induction of apoptosis since silencing of the pro-autophagic genes attenuates the TGFβ-mediated growth inhibition and the induction of pro-apoptotic genes. In another work, Korah et al.51 reported that TGFβ-dependent induction of autophagy is mediated by the activation of the pRB/E2F1 axis.51 Silencing E2F1 impairs the ability of TGFβ to transcriptionally induce the expression of pro-autophagic genes. The same authors in a previous work reported that activation of the pRB/E2F1 axis is critical for the induction of multiple TGFβ-targeted genes involved in tumor suppression, leading to apoptosis and cell growth inhibition.54 Based on this observation, it appears that, in cancer cells, TGFβ activation of autophagy is functionally linked to the TGFβ-dependent tumor suppressive effects. We recently showed that TGFβ treatment in normal and thyroid cancer cell lines induces EMT through the activation of RUNX2 and its target CDH6.55, 56, 57 CDH6 silencing reverts the EMT phenotype and restrains migration and invasiveness in thyroid cancer cells. Noticeably, we demonstrated that CDH6 interacts with GABARAP and that CDH6 silencing also induces a massive activation of autophagy.34 Even if further experiments are needed, these evidence suggests that autophagy may negatively control EMT and that common signaling pathways control the dynamics of both processes. Furthermore, these observations identify CDH6 as a necessary mediator of the interplay between autophagy and EMT, uncovering a previously unknown function of Cadherins. Indeed, the interaction of CDH6 with the autophagic machinery is mediated by a structural epitope containing four sequential LIR domains that are strongly conserved in the cytoplasmic domain of the other Cadherins including E-CAD and N-CAD.
The activation of autophagy observed upon silencing of CDH6 is associated with a profound repression of AKT phosphorylation. The PI3K-I/AKT/mTOR is another non-SMAD pathway that can be activated in response to TGFβ.48 The activation of this pathway has been mainly linked to the EMT-promoting effect of TGFβ. mTOR is the catalytic subunit of two enzymatic complexes named mTORC1 and mTORC2 both of which may be activated by TGFβ signaling.58 During EMT, TGFβ promotes the increase of cell size, which is necessary to sustain cell migration and invasiveness.59, 60 This effect is mediated by mTORC1 which phosphorylates and activates the S6 kinase 1 (S6K1) and the eukaryotic initiation factor 4E-binding protein 1 (4E-BP1), both of which are direct regulators of translation initiation.61, 62 TGFβ also induces mTORC2 kinase activity, which is required during the later phase to complete EMT. Loss of mTORC2 activity blocks cancer cell dissemination and metastasis formation in mouse models.63 In particular, mTORC2 phosphorylates and activates both RAC1 and PKCa both of which partake to the profound cytoskeleton reorganization that accompanies and sustains the morphological and functional changes of the cells during EMT.64 Furthermore, mTORC2 promotes cell invasiveness through the SNAIL-dependent upregulation of MMP9.65 Noticeably, the activation of the PI3K/AKT/mTOR pathway is the major inhibitory signal of autophagy.58 When activated, the mTORC1 complex leads to the phosphorylation and consequential inactivation of the serine/threonine UNC-51-like kinase (ULK1) that regulates the formation of autophagophores. The block of ULK1 activity results in the inhibition of the entire autophagic process.66 Thus, while promoting EMT through both SMAD-dependent and independent pathways, TGFβ may restrain autophagy by mTORC1 mediated ULK1 inhibition.
Even if experimental evidence is still limited, it is reasonable to speculate that TGFβ is able to trigger both pro-autophagic and anti-autophagic signals and the choice may be dependent on cellular context and on the cancer progression phase. In the early phases of tumor formation TGFβ promotes autophagy as part of the TGFβ-dependent tumor suppressive program. Later in tumor progression, TGFβ restrains autophagy while inducing EMT and promoting metastatic spreading of cancer cells (Figures 3 and 4).
STAT3
As discussed above, several transcription factors are involved in EMT. Recently a relevant role of the transcription factor Signal Transducer and Activator of Transcription 3 (STAT3) in promoting EMT has been proposed.67 The aberrant expression of interleukin 6 (IL-6) and its activation of STAT3 have been correlated with the development and progression of carcinomas68 and in particular with increased metastatic potential and poor outcome in epithelial tumors.69 IL-6-STAT3 signaling promotes the initiation of EMT and the acquisition of mesenchymal features in breast and head and neck cancers, by inducing the expression of Twist and Snail. In turn, TWIST upregulates the production of IL-6, leading to autocrine activation of STAT3.70 Saitoh and colleagues showed that STAT3 acts as molecular mediator of the synergism between TGFβ and RAS signals during EMT. In particular, these authors observed that upon TGFβ stimulation, STAT3 dissociates from Protein Inhibitor of Activated STAT3 (PIAS3) and, in cooperation with the RAS signaling, induces the expression of SNAIL and the progression of the EMT process.71 Intriguingly, evidence for a non-transcriptional role of STAT3 in controlling cytoskeleton organization has been proposed. In particular, STAT3 has been shown to interact with the microtubule (MT)-destabilizing protein STATHMIN, inhibiting its function. The expression of STAT3 is required for the stabilization of microtubules and cell migration.72
STAT3 is one of the major signaling pathways activated in response to stress, but it is also known to control autophagy in various ways.73 Cytoplasmic STAT3 constitutively inhibits autophagy in a transcription-independent manner. Shen and colleagues, in a screening designed to identify novel inducers of autophagy, showed that inhibitors of STAT3 induced a strong activation of autophagy.74 These authors show that the SH2 domain of STAT3 mediates its interaction with the catalytic domain of the eIF2α kinase 2 (EIF2AK2), also known as protein kinase R (PKR), inhibiting its function. This inhibition blocks the phosphorylation of eIF2α and its pro-autophagic function, thus restraining the autophagic flux. Beside, cytoplasmic STAT3 inhibits autophagy also by interacting with other autophagy-related signaling molecules such as Forkhead box protein O1 (FOXO1) and FOXO3.75 Nuclear STAT3 also controls autophagy by fine tuning several autophagy-related genes. In this context, STAT3 may promote as well as restrain autophagy depending on its targets. Nuclear STAT3 executes antiautophagic functions by upregulating negative regulators of autophagy such as BCL2, BCL2L1, MCL1, PIK3R1/p55α and PIK3R1/p50α.76, 77, 78 Furthermore, STAT3 disrupts the formation of the pro-autophagic BCN1/PI3K-III complex by recruiting histone deacetylase 3 (HDAC3) to the promoter of BECN1 and repressing its expression. During EMT Integrin profiles and Integrin-ECM contacts undergo profound reorganization (Figure 4).
Integrins and focal adhesion
The diversity in binding affinities of different Integrins enables cells to respond to a vast variety of stimuli and activate intracellular cascades that cooperate to initiation and completion of EMT.79 Noticeably, stimulation of Integrins by ECM components leads to the activation of the Integrin-linked kinase (ILK) that promotes the phosphorylation of AKT and the consequential activation of the AKT–mTOR cascade, which we have already discussed to be the major inhibitory signal of autophagy.80
Recently, it has been shown that inhibition of Integrins in glioma cells causes massive cell detachment and death due to the activation of an atypical anoikis. This effect was associated with a strong inhibition of the TGFβ pathway and the parallel activation of autophagy, again suggesting an intimate and reciprocal interaction between EMT and autophagy controlling mechanisms.81, 82
Focal adhesions (FAs) are Integrin-based multiprotein complexes that link ECM to intracellular actin cytoskeleton and are responsible for the translation of mechanical forces and other regulatory stimuli within the cells. FAs are highly dynamic structure that may rapidly assemble and disassemble at the edge of moving cells, controlling migration.83, 84, 85, 86, 87, 88 FAs appear to be a central hub of the crosstalk between autophagy and EMT. Several papers demonstrate that autophagy participate to FA turnover affecting cell migration.81, 89, 90 As reciprocal feedback, FAs control autophagy, mainly through the FAK–Src signaling pathway.25, 26 By selective targeting FA proteins to autophagosome degradation, autophagy promotes FA disassembly and sustains cell migration. During this process autophagosomes localize to dynamic FAs and selectively sequestrate FA components (paxilin, vinculin, etc.) into autophagosomes, promoting local FA destabilization and disassembly.89, 90 However, depletion of ATG proteins not only reduces FAs disassembly but also negatively affect their assembly, suggesting that autophagy participates also to stabilization of FAs, likely through more indirect mechanisms.89 Indeed, Tuloup-Minguez et al.81 showed that autophagy selectively targets and degrades Integrin β1, mitigating Integrins surface expression and inhibiting cell migration.81
As discussed above, impairment of FAK–Src signaling either by loss of function or by impaired FAK phosphorylation triggers autophagy activation.25, 26 Of note, the FAK–Src axis contributes to EMT by promoting the acquisition of a mesenchymal phenotype through different mechanisms.83, 84, 85, 86, 87, 88 Noticeably, in cancer cells overexpression of FAK mutants unable to be phosphorylated or pharmacological inhibition of FAK kinase activity restrain EMT by blocking the SRC-induced internalization of E-cadherin, increasing cell adhesion strength.84, 85 Taken together, this evidence indicates that FAK inhibition both restrains EMT and promotes selective autophagy. To establish whether a functional link between these two events exists, further experimental proofs are still required. However, the centrality of FAs and FAK–Src axis in the regulation of these processes highlights the relevance of mechanical stimuli and cell structure regulation at the crossroad between autophagy and EMT (Figure 4).
Autophagy and EMT in Cancer: Is it a Matter of Cytoskeleton and Mitochondria?
Cytoskeleton remodeling is crucial to accomplish EMT.91, 92 Changes in the adhesion molecule profile (like the Cadherin switch or FAs remodeling) during EMT determine the activation of actin polymerization and the formation of non-polarized thick fibers named stress fibers.93 These cytoskeleton structures are necessary to support cell movement and to sustain mechanical stress imposed on cells by the loss of cell–cell and cell–ECM interactions.94 Cytoskeleton remodeling is not just the default consequence of EMT activation, but it plays a regulatory role in this process.17, 95 Depolymerization of the actin cytoskeleton reduces cell size, changes cell shape and reverses EMT phenotype in cancer cells.17, 95, 96, 97, 98 Furthermore, depolymerization of actin filaments induces the nucleus to cytoplasm translocation of SNAIL, leading to re-expression of E-CAD and inhibition of EMT.17
Mitochondria are highly versatile organelles, which are prominent players of energy conversion and integrate a number of signaling pathways. Cytoskeleton and mitochondria are linked in a tight functional relationship, which is particularly relevant in the regulation of cell migration (Figure 5). Beside their morphological plasticity, mitochondria are characterized by the ability to move across the cells to specialized cellular sites where their energy support is majorly required. Movement and localization of mitochondria within the cells are determined by their interaction with the cytoskeleton.97 In particular, the interaction of mitochondria with microtubules and actin filaments carries mitochondria around the cells, 98 while the interaction with intermediate filaments serves to stop mitochondria in specialized cellular sites.99, 100 Accumulation of mitochondria below the cell membrane is necessary to promote the formation of filopodia and lamellipodia, cellular structure for motility during EMT.101, 102 Pharmacological inhibition of PI3K pathway in cancer cells promotes cell motility. This effect is mediated by the increased trafficking of energetically active mitochondria to the cortical cytoskeleton of tumor cells where they support FA turnover, membrane protrusion dynamics, migration and invasiveness.103
The functional versatility of mitochondria is dependent on their morphological and structural plasticity. Mitochondria fuse and fragment during cell life appearing either as short round-shaped units or as elongated branches forming a network.104 The morphological appearance of mitochondria in a cell is dependent on the balance between the two opposing processes of fission (fragmentation into single units) and fusion (melting of mitochondria into a well-structured network). Profound changes in the structure of mitochondrial network occur in cancer.
Increased mitochondrial fission and loss of mitochondrial network have been described as features of oncogenic transformation105 and increased cancer aggressiveness.106, 107 Furthermore, the GTPase DRP1, which drives mitochondrial fission, is strongly upregulated in metastatic as compared with non-metastatic cancer cells,108, 109 confirming that a fractioned network and single unit mitochondria are required during cancer progression.
In order to be moved around the cells, mitochondria need to be as single units, free from the tight network organization. Convincing evidence indicates that actin polymerization promotes mitochondrial fission.110, 111, 112, 113, 114, 115, 116 In addition, Xu et al.117 showed that activation of the EMT program by TGFβ in A549 lung cancer cells leads to a significant increase in the overall mitochondrial content. Vice versa, actin-depolymerizing drugs have been shown to inhibit the recruitment of DRP1 to mitochondria and, as a consequence, to inhibit the reduction of mitochondrial length.
Also autophagy participates to the control of mitochondrial dynamics. Mitochondria can be degraded either through non-selective autophagy or through a cargo-selective specific autophagy called mitophagy.118, 119, 120, 121, 122 Mitophagy activation requires mitochondrial fission.123, 124 Upon fission, mitochondria expose a kind of ‘eat me’ signal that targets mitochondria to autophagosomes for degradation. By contrast, the massive activation of unselective autophagy induces mitochondria fusion.125, 126, 127 Elongated fused mitochondria are spared from autophagy degradation and may help to optimize ATP production during starvation. Both high levels of mitophagy or unselective autophagy result in a reduced availability of free mitochondria within the cells with an impact on the formation of structures like filopodia and lamellipodia and thus a reduction of cell migratory capacity.
Based on these observations, it is tempting to speculate that the regulation of mitochondria and cytoskeleton dynamics and of their functional interplay represents a preferential and rapid way of interaction between EMT and autophagy (Figure 5). EMT activation changes the cell adhesion profile leading to cytoskeleton remodeling. Actin polymerization in turn promotes fragmentation and trafficking of mitochondria to the cortical regions where they provide energy supplies for motility membrane protrusions and cell migration. By contrast, activation of autophagy reduces the number of available free mitochondria counteracting the EMT phenotype.
Even if definitive evidence is still missing the first experimental indications supporting this model have recently begun to emerge.
Metabolic reprogramming is an important driver of cancer progression. Even if under extremely unfavorable energetic conditions, metastatic cancer cells manage to acquire highly energetically demanding features like migration and invasiveness. Mitochondria activity seems to be crucial in this process. Caino and colleagues showed that under nutrient deprivation condition, cancer cells preserve cytoskeletal dynamics and motility through the chaperone function of mitochondrial associated HSP90. Functional maintenance of HSP90 mitochondrial target proteins guaranties residual oxidative phosphorylation and ATP production preventing autophagy activation. Inhibition of autophagy restrains the sequestration and consequential inhibition of FAK by the ULK1/Atg13/FIP200 autophagic complex, supporting cell motility and migration.128
A recent work showed that the mitochondrial protein BNIP3 controls plasticity of actin cytoskeleton and cell motility in melanoma.129 BNIP3 is engaged in mitophagy since it mediates the interaction of mitochondria with the autophagosome ATG8 proteins (LC3 and GABARAP) to promote mitophagy. Ablation of BNIP3 induces structural changes in the adhesion properties of melanoma cells and a strong reorganization of the actin filaments. These changes determine the reduction of lamellipodia and filopodia formation and of the migratory capacity of melanoma cells. We recently found BNIP3 and BNIP3L (together with GABARAP) as CDH6 interactors in thyroid cancer cells. Noticeably, upon CDH6 silencing we observed a phenotype similar to the one showed by BNIP3 silenced melanoma cells. In particular, loss of CDH6 causes a profound reorganization of cytoskeleton with a marked reduction of cell surface protrusions and reversion of the EMT phenotype. This effect is accompanied by a massive activation of autophagy and by profound alterations of mitochondria that in the absence of CDH6 fuse into a well-organized network, revealing an unexpected link between Cadherins and mitochondrial dynamic.34
Conclusion
During cancer progression, a complex and non-linear relationship links EMT and autophagy. The interplay between these biological processes is influenced by several aspects and functionally evolves throughout the different phases of tumor development and progression. This complexity is reflected by the intricate web of regulatory signaling pathways that converge on the regulation of EMT and autophagy and that may alter the reciprocal equilibrium between these two processes.
The tight relationship between cytoskeleton and mitochondria and their importance in regulating both these processes is emerging as a novel layer of reciprocal regulation between EMT and autophagy that deserves further investigations.
Furthermore, the recently observed ability of membrane proteins like Integrins or Cadherin to affect autophagy underlines the complexity of these proteins functions, which may not any longer being considered merely structural proteins.
References
Hanahan D, Weinberg RA . Hallmarks of cancer: the next generation. Cell 2011; 144: 646–674.
Boya P, Reggiori F, Codogno P . Emerging regulation and functions of autophagy. Nat Cell Biol 2013; 15: 713–720.
Kroemer G, Marino G, Levine B . Autophagy and the integrated stress response. Mol Cell 2010; 40: 280–293.
Izuishi K, Kato K, Ogura T, Kinoshita T, Esumi H . Remarkable tolerance of tumor cells to nutrient deprivation: possible new biochemical target for cancer therapy. Cancer Res 2000; 60: 6201–6207.
Mathew R, Karantza-Wadsworth V, White E . Role of autophagy in cancer. Nat Rev Cancer 2007; 7: 961–967.
Harris AL . Hypoxia—a key regulatory factor in tumour growth. Nat Rev Cancer 2002; 2: 38–47.
Galluzzi L, Pietrocola F, Bravo-San Pedro JM, Amaravadi RK, Baehrecke EH, Cecconi F et al. Autophagy in malignant transformation and cancer progression. EMBO J 2015; 34: 856–880.
Kalluri R, Weinberg RA . The basics of epithelial-mesenchymal transition. J Clin Invest 2009; 119: 1420–1428.
Kalluri R . EMT: when epithelial cells decide to become mesenchymal-like cells. J Clin Invest 2009; 119: 1417–1419.
Thiery JP, Acloque H, Huang RY, Nieto MA . Epithelial-mesenchymal transitions in development and disease. Cell 2009; 139: 871–890.
Polyak K, Weinberg RA . Transitions between epithelial and mesenchymal states: acquisition of malignant and stem cell traits. Nat Rev Cancer 2009; 9: 265–273.
Lecuit T, Le Goff L . Orchestrating size and shape during morphogenesis. Nature 2007; 450: 189–192.
Sauka-Spengler T, Bronner-Fraser M . A gene regulatory network orchestrates neural crest formation. Nat Rev Mol Cell Biol 2008; 9: 557–568.
Fidler IJ, Poste G . The ‘seed and soil’ hypothesis revisited. Lancet Oncol 2008; 9: 808.
Montell DJ . Morphogenetic cell movements: diversity from modular mechanical properties. Science 2008; 322: 1502–1505.
Rogers CD, Saxena A, Bronner ME . Sip1 mediates an E-cadherin-to-N-cadherin switch during cranial neural crest EMT. J Cell Biol 2013; 203: 835–847.
Shankar J, Nabi IR . Actin cytoskeleton regulation of epithelial mesenchymal transition in metastatic cancer cells. PLoS One 2015; 10: e0119954.
Tojkander S, Gateva G, Lappalainen P . Actin stress fibers assembly, dynamics and biological roles. J Cell Sci 2012; 125 (Pt 8): 1855–1864.
Kroemer G, Marino G, Levine B . Autophagy and the integrated stress response. Mol Cell 2010; 40: 280–293.
Lazova R, Camp RL, Klump V, Siddiqui SF, Amaravadi RK, Pawelek JM . Punctate LC3B expression is a common feature of solid tumors and associated with proliferation, metastasis, and poor outcome. Clin Cancer Res 2012; 18: 370–379.
Mikhaylova O, Stratton Y, Hall D, Kellner E, Ehmer B, Drew AF et al. VHL-regulated MiR-204 suppresses tumor growth through inhibition of LC3B-mediated autophagy in renal clear cell carcinoma. Cancer Cell 2012; 21: 532–546.
Avivar-Valderas A, Bobrovnikova-Marjon E, Alan DJ, Bardeesy N, Debnath J, Aguirre-Ghiso JA . Regulation of autophagy during ECM detachment is linked to a selective inhibition of mTORC1 by PERK. Oncogene 2013; 32: 4932–4940.
Cai Q, Yan L, Xu Y . Anoikis resistance is a critical feature of highly aggressive ovarian cancer cells. Oncogene 2014; 34: 3315–3324.
Fung C, Lock R, Gao S, Salas E, Debnath J . Induction of autophagy during extracellular matrix detachment promotes cell survival. Mol Biol Cell 2008; 19: 797–806.
Sandilands E, Serrels B, McEwan DG, Morton JP, Macagno JP, McLeod K et al. Autophagic targeting of Src promotes cancer cell survival following reduced FAK signalling. Nat Cell Bio 2011; 14: 51–60.
Sandilands E, Serrels B, Wilkinson S, Frame MC . Src-dependent autophagic degradation of Ret. EMBO Rep 2012; 13: 733–740.
Peng YF, Shi YH, Ding ZB, Ke AW, Gu CY, Hui B et al. Autophagy inhibition suppresses pulmonary metastasis of HCC in mice via impairing anoikis resistance and colonization of HCC cells. Autophagy 2013; 9: 2056–2068.
Sahni S, Bae DH, Lane DJ, Kovacevic Z, Kalinowski DS, Jansson PJ et al. The metastasis suppressor, N-myc downstream-regulated gene 1 (NDRG1), inhibits stress-induced autophagy in cancer cells. J Biol Chem 2014; 289: 9692–9709.
Akalay I, Janji B, Hasmim M, Noman MZ, André F, De Cremoux P et al. Epithelial-to-mesenchymal transition and autophagy induction in breast carcinoma promote escape from T-cell-mediated lysis. Cancer Res 2013; 73: 2418–2427.
Lv Q, Wang W, Xue J, Hua F, Mu R, Lin H et al. DEDD interacts with PI3KC3 to activate autophagy and attenuate epithelial-mesenchymal transition in human breast cancer. Cancer Res 2012; 72: 3238–3250.
Qiang L, Zhao B, Ming M, Wang N, He TC, Hwang S et al. Regulation of cell proliferation and migration by p62 through stabilization of Twist1. Proc Natl Acad Sci USA 2014; 111: 9241–9246.
Li G, Li CX, Xia M, Ritter JK, Gehr TW, Boini K et al. Enhanced epithelial-to-mesenchymal transition associated with lysosome dysfunction in podocytes: role of p62/Sequestosome 1 as a signaling hub. Cell Physiol Biochem 2015; 35: 1773–1786.
Catalano M, D'Alessandro G, Lepore F, Corazzari M, Caldarola S, Valacca C et al. Autophagy induction impairs migration and invasion by reversing EMT in glioblastoma cells. Mol Oncol 2015; 9: 1612–1625.
Gugnoni M, Sancisi V, Gandolfi G, Manzotti G, Ragazzi M, Giordano D et al. Cadherin-6 promotes EMT and cancer metastasis by restraining autophagy. Oncogene 2016 (doi:10.1038/onc.2016.237; e-pub ahead of print).
Subramani R, Gonzalez E, Arumugam A, Nandy S, Gonzalez V, Medel J et al. Nimbolide inhibits pancreatic cancer growth and metastasis through ROS-mediated apoptosis and inhibition of epithelial-to-mesenchymal transition. Sci Rep 2016; 6: 19819.
Ren BJ, Zhou ZW, Zhu DJ, Ju YL, Wu JH, Ouyang MZ et al. Alisertib induces cell cycle arrest, apoptosis, autophagy and suppresses EMT in HT29 and Caco-2 cells. Int J Mol Sci 2015; 17: 41.
Zi D, Zhou ZW, Yang YJ, Huang L, Zhou ZL, He SM et al. Danusertib induces apoptosis, cell cycle arrest, and autophagy but inhibits epithelial to mesenchymal transition involving PI3K/Akt/mTOR signaling pathway in human ovarian cancer cells. Int J Mol Sci 2015; 16: 27228–27251.
Massagué J . TGFβ signalling in context. Nat Rev Mol Cell Biol 2012; 13: 616–630.
Heldin CH, Vanlandewijck M, Moustakas A . Regulation of EMT by TGFβ in cancer. FEBS Lett 2012; 586: 1959–1970.
Bertrand M, Petit V, Jain A, Amsellem R, Johansen T, Larue L et al. SQSTM1/p62 regulates the expression of junctional proteins through epithelial-mesenchymal transition factors. Cell Cycle 2015; 14: 364–374.
Grassi G, Di Caprio G, Santangelo L, Fimia GM, Cozzolino AM, Komatsu M et al. Autophagy regulates hepatocyte identity and epithelial to-mesenchymal and mesenchymal-to-epithelial transitions promoting Snail degradation. Cell Death Dis 2015; 6: e1880.
Gonzalez DM, Medici D . Signaling mechanisms of the epithelial-mesenchymal transition. Sci Signal 2014; 7: re8.
Puisieux A, Brabletz T, Caramel J . Oncogenic roles of EMT-inducing transcription factors. Nat Cell Biol 2014; 16: 488–494.
Lamouille S, Xu J, Derynck R . Molecular mechanisms of epithelial-mesenchymal transition. Nat Rev Mol Cell Biol 2014; 15: 178–196.
Galluzzi L, Pietrocola F, Levine B, Kroemer G . Metabolic control of autophagy. Cell 2014; 159: 1263–1276.
Pietrocola F, Izzo V, Niso-Santano M, Vacchelli E, Galluzzi L, Maiuri MC et al. Regulation of autophagy by stress-responsive transcription factors. Semin Cancer Biol 2013; 23: 310–322.
Lorina S, Hamaïb A, Mehrpourb M, Codognob P . Autophagy regulation and its role in cancer. Semin Cancer Biol 2013; 23: 361–379.
Massagué J . How cells read TGF-beta signals. Nat Rev Mol Cell Biol 2000; 1: 169–178.
Kiyono K, Suzuki HI, Matsuyama H, Morishita Y, Komuro A, Kano MR et al. Autophagy is activated by TGF-beta and potentiates TGF-beta-mediated growth inhibition in human hepatocellular carcinoma cells. Cancer Res 2009; 69: 8844–8852.
Suzuki HI, Kiyono K, Miyazono K . Regulation of autophagy by transforming growth factor-β (TGF-β signaling. Autophagy 2010; 6: 645–647.
Korah J, Canaff L, Lebrun JJ . The retinoblastoma tumor suppressor protein (pRb)/E2 promoter binding factor 1 (E2F1) pathway as a novel mediator of TGFβ-induced autophagy. J Biol Chem 2016; 291: 2043–2054.
Frassanito MA, De Veirman K, Desantis V, Marzo LD, Vergara D, Ruggieri S et al. Halting pro-survival autophagy by TGFβ inhibition in bone marrow fibroblasts overcomes bortezomib resistance in multiple myeloma patients. Leukemia 2016; 30: 640–648.
Liu FL, Mo EP, Yang L, Du J, Wang HS, Zhang H et al. Autophagy is involved in TGF-β1-induced protective mechanisms and formation of cancer-associated fibroblasts phenotype in tumor microenvironment. Oncotarget 2016; 7: 4122–4141.
Korah J, Falah N, Lacerte A, Lebrun JJ . A transcriptionally active pRb-E2F1-P/CAF signaling pathway is central to TGFβ-mediated apoptosis. Cell Death Dis 2012; 3: e407.
Ciarrocchi A, Piana S, Valcavi R, Gardini G, Casali B . Inhibitor of DNA binding-1 induces mesenchymal features and promotes invasiveness in thyroid tumour cells. Eur J Cancer 2011; 47: 934–945.
Sancisi V, Borettini G, Maramotti S, Ragazzi M, Tamagnini I, Nicoli D et al. Runx2 isoform I controls a panel of proinvasive genes driving aggressiveness of papillary thyroid carcinomas. J Clin Endocrinol Metab 2012; 97: E2006–E2015.
Sancisi V, Gandolfi G, Ragazzi M, Nicoli D, Tamagnini I, Piana S et al. Cadherin 6 is a new RUNX2 target in TGF-β signalling pathway. PLoS One 2013; 8: e75489.
Beauchamp EM, Platanias LC . The evolution of the TOR pathway and its role in cancer. Oncogene 2013; 32: 3923–3932.
Fingar DC, Richardson CJ, Tee AR, Cheatham L, Tsou C, Blenis J . mTOR controls cell cycle progression through its cell growth effectors S6K1 and 4E-BP1/eukaryotic translation initiation factor 4E. Mol Cell Biol 2004; 24: 200–216.
Lamouille S, Derynck R . Cell size and invasion in TGF-beta-induced epithelial to mesenchymal transition is regulated by activation of the mTOR pathway. J Cell Biol 2007; 178: 437–451.
Hershey JWB, Merrick WC The Pathway and Mechanism of Initiation of Protein Synthesis. Translational Control of Gene Expression. Cold Spring Harbor Laboratory Press, 2000 pp 33–88.
Rogers GW Jr, Komar AA, Merrick WC . eIF4A: the godfather of the DEAD box helicases. Prog Nucleic Acid Res Mol Biol 2002; 72: 307–331.
Lamouille S, Connolly E, Smyth JW, Akhurst RJ, Derynck R . TGF-β-induced activation of mTOR complex 2 drives epithelial-mesenchymal transition and cell invasion. J Cell Sci 2012; 125 (Pt 5): 1259–1273.
Ma XM, Blenis J . Molecular mechanisms of mTOR mediated translational control. Mol Cell Biol 2009; 10: 307–318.
Jordà M, Olmeda D, Vinyals A, Valero E, Cubillo E, Llorens A et al. Upregulation of MMP-9 in MDCK epithelial cell line in response to expression of the Snail transcription factor. J Cell Sci 2005; 118: 3371–3385.
O′Farrell F, Rusten TE, Stenmark H . Phosphoinositide 3-kinases as accelerators and brakes of autophagy. FEBS J 2013; 280: 6322–6337.
Wendt MK, Balanis N, Carlin CR, Schiemann WP . STAT3 and epithelial–mesenchymal transitions in carcinomas. JAKSTAT 2014; 3: e28975.
Guo Y, Xu F, Lu T, Duan Z, Zhang Z . Interleukin-6 signaling pathway in targeted therapy for cancer. Cancer Treat Rev 2012; 38: 904–910.
Xie G, Yao Q, Liu Y, Du S, Liu A, Guo Z et al. IL-6-induced epithelial-mesenchymal transition promotes the generation of breast cancer stem-like cells analogous to mammosphere cultures. Int J Oncol 2012; 40: 117–119.
Sullivan NJ, Sasser AK, Axel AE, Vesuna F, Raman V, Ramirez N et al. Interleukin-6 induces an epithelial-mesenchymal transition phenotype in human breast cancer cells. Oncogene 2009; 28: 2940–2947.
Saitoh M, Endo K, Furuya S, Minami M, Fukasawa A, Imamura T et al. STAT3 integrates cooperative Ras and TGF-β signals that induce Snail expression. Oncogene 2015; 35: 1049–1057.
Verma NK, Dourlat J, Davies AM, Long A, Liu WQ, Garbay C et al. STAT3-stathmin interactions control microtubule dynamics in migrating T-cells. J Biol Chem 2009; 284: 12349–12362.
You L, Wang Z, Li H, Shou J, Jing Z, Xie J et al. The role of STAT3 in autophagy. Autophagy 2015; 11: 729–739.
Shen S, Niso-Santano M, Adjemian S, Takehara T, Malik SA, Minoux H et al. Cytoplasmic STAT3 represses autophagy by inhibiting PKR activity. Mol Cell 2012; 48: 667–680.
Oh HM, Yu CR, Dambuza I, Marrero B, Egwuagu CE . STAT3 protein interacts with Class O Forkhead transcription factors in the cytoplasm and regulates nuclear/cytoplasmic localization of FoxO1 and FoxO3a proteins in CD4(+) T cells. J Biol Chem 2012; 287: 30436–30443.
Bowman T, Garcia R, Turkson J, Jove R . STATs in oncogenesis. Oncogene 2000; 19: 2474–2488.
Fukada T, Hibi M, Yamanaka Y, Takahashi-Tezuka M, Fujitani Y, Yamaguchi T et al. Two signals are necessary for cell proliferation induced by a cytokine receptor gp130: involvement of STAT3 in anti-apoptosis. Immunity 1996; 5: 449–460.
Pensa S, Lloyd-Lewis B, Sargeant TJ, Resemann HK, Kahn CR, Watson CJ . Signal transducer and activator of transcription 3 and the phosphatidylinositol 3-kinase regulatory subunits p55alpha and p50alpha regulate autophagy in vivo. FEBS J 2014; 281: 4557–4567.
Yilmaz M, Christofori G . EMT, the cytoskeleton, and cancer cell invasion. Cancer Metastasis Rev 2009; 28: 15–33.
McDonald PC, Fielding AB, Dedhar S . Integrin-linked kinase—essential roles in physiology and cancer biology. J Cell Sci 2008; 121: 3121–3132.
Tuloup-Minguez V, Hamaï A, Greffard A, Nicolas V, Codogno P, Botti J . Autophagy modulates cell migration and β1 integrin membrane re cycling. Cell Cycle 2013; 12: 3317–3328.
Silginer M, Weller M, Ziegler U, Roth P . Integrin inhibition promotes atypical anoikis in glioma cells. Cell Death Dis 2014; 5: e1012.
Cicchini C, Laudadio I, Citarella F, Corazzari M, Steindler C, Conigliaro A et al. TGFbeta-induced EMT requires focal adhesion kinase (FAK) signaling. Exp Cell Res 2008; 314: 143–152.
Avizienyte E, Wyke AW, Jones RJ, McLean GW, Westhoff MA, Brunton VG et al. Src-induced de-regulation of E-cadherin in colon cancer cells requires integrin signalling. Nat Cell Biol 2002; 4: 632–638.
Canel M, Serrels A, Miller D, Timpson P, Serrels B, Frame MC et al. Quantitative in vivo imaging of the effects of inhibiting integrin signaling via Src and FAK on cancer cell movement: effects on E-cadherin dynamics. Cancer Res 2010; 70: 9413–9422.
Kong X, Li G, Yuan Y, He Y, Wu X, Zhang W et al. MicroRNA-7 inhibits epithelial-to-mesenchymal transition and metastasis of breast cancer cells via targeting FAK expression. PLos One 2012; 7: e41523.
Li XY, Zhou X, Rowe RG, Hu Y, Schlaepfer DD, Ilić D et al. Snail1 controls epithelial-mesenchymal lineage commitment in focal adhesion kinase-null embryonic cells. J Cell Biol 2011; 195: 729–738.
Sulzmaier FJ, Jean C, Schlaepfer DD . FAK in cancer: mechanistic findings and clinical applications. Nat Rev Cancer 2014; 14: 598–610.
Kenific CM, Stehbens SJ, Goldsmith J, Leidal AM, Faure N, Ye J et al. Cell Biol 2016; 212: 577–590.
Sharifi MN, Mowers EE, Drake LE, Collier C, Chen H, Zamora M et al. Autophagy promotes focal adhesion disassembly and cell motility of metastatic tumor cells through the direct interaction of Paxillin with LC3. Cell Rep 2016; 15: 1660–1672.
Wei SC, Yang J . Forcing through tumor metastasis: the interplay between tissue rigidity and epithelial-mesenchymal transition. Trends Cell Biol 2016; 26: 111–120.
Samuel MS, Lopez JI, McGhee EJ, Croft DR, Strachan D, Timpson P et al. Actomyosin-mediated cellular tension drives increased tissue stiffness and beta-catenin activation to induce epidermal hyperplasia and tumor growth. Cancer Cell 2011; 19: 776–791.
Scarpa E, Szabò A, Bibonne A, Theveneau E, Parsons M, Mayor R . Cadherin switch during EMT in neural crest cells leads to contact inhibition of locomotion via repolarization of forces. Dev Cell 2015; 34: 421–434.
Tojkander S, Gateva G, Lappalainen P . Actin stress fibers- assembly, dynamics and biological roles. J Cell Sci 2012; 125: 1855–1864.
Liu CY, Lin HH, Tang MJ, Wang YK . Vimentin contributes to epithelial-mesenchymal transition cancer cell mechanics by mediating cytoskeletal organization and focal adhesion maturation. Oncotarget 2015; 6: 15966–15983.
Shankar J, Messenberg A, Chan J, Underhill TM, Foster LJ, Nabi IR . Pseudopodial actin dynamics control epithelial-mesenchymal transition in metastatic cancer cells. Cancer Res 2010; 70: 3780–3790.
Anesti V, Scorrano L . The relationship between mitochondrial shape and function and the cytoskeleton. Biochim Biophys Acta 2006; 1757 (5–6): 692–699.
Hollenbeck PJ, Saxton WM . The axonal transport of mitochondria. J Cell Sci 2005; 118: 5411–5419.
Cerqua C, Anesti V, Pyakurel A, Liu D, Naon D, Wiche G et al. Trichoplein/mitostatin regulates endoplasmic reticulum-mitochondria juxtaposition. EMBO Rep 2010; 11: 854–860.
Milner DJ, Mavroidis M, Weisleder N, Capetanaki Y . Desmin cytoskeleton linked to muscle mitochondrial distribution and respiratory function. J Cell Biol 2000; 150: 1283.
Zhao J, Zhang J, Yu M, Xie Y, Huang Y, Wolff DW et al. Mitochondrial dynamics regulates migration and invasion of breast cancer cells. Oncogene 2013; 32: 4814–4824.
Ketschek A, Gallo G . Nerve growth factor induces axonal filopodia through localized microdomains of phosphoinositide 3-kinase activity that drive the formation of cytoskeletal precursors to filopodia. J Neurosci 2010; 30: 12185–12197.
Caino MC, Ghosh JC, Chae YC, Vaira V, Rivadeneira DB, Faversani A et al. PI3K therapy reprograms mitochondrial trafficking to fuel tumor cell invasion. Proc Natl Acad Sci USA 2015; 112: 8638–8643.
Campello S, Scorrano L . Mitochondrial shape changes: orchestrating cell pathophysiology. EMBO Rep 2010; 11: 678–684.
Serasinghe MN, Wieder SY, Renault TT, Elkholi R, Asciolla JJ, Yao JL et al. Mitochondrial division is requisite to RAS-induced transformation and targeted by oncogenic MAPK pathway inhibitors. Mol Cell 2015; 57: 521–536.
Kashatus JA, Nascimento A, Myers LJ, Sher A, Byrne FL, Hoehn KL et al. Erk2 phosphorylation of Drp1 promotes mitochondrial fission and MAPK-driven tumor growth. Mol Cell 2015; 57: 537–551.
Rehman J, Zhang HJ, Toth PT, Zhang Y, Marsboom G, Hong Z et al. Inhibition of mitochondrial fission prevents cell cycle progression in lung cancer. FASEB J 2012; 26: 2175–2186.
Xie Q, Wu Q, Horbinski CM, Flavahan WA, Yang K, Zhou W et al. Mitochondrial control by DRP1 in brain tumor initiating cells. Nat Neurosci 2015; 18: 501–510.
Zhao J, Zhang J, Yu M, Xie Y, Huang Y, Wolff DW et al. Mitochondrial dynamics regulates migration and invasion of breast cancer cells. Oncogene 2013; 32: 4814–4824.
Manor U, Bartholomew S, Golani G, Christenson E, Kozlov M, Higgs H et al. A mitochondria-anchored isoform of the actin-nucleating spire protein regulates mitochondrial division. Elife 2015; 25: 4.
Korobova F, Ramabhadran V, Higgs HN . An actin-dependent step in mitochondrial fission mediated by the ER-associated formin INF2. Science 2013; 339: 464–467.
Ji WK, Hatch AL, Merrill RA, Strack S, Higgs HN . Actin filaments target the oligomeric maturation of the dynamin GTPase Drp1 to mitochondrial fission sites. Elife 2015; 4: e11553.
Li S, Xu S, Roelofs BA, Boyman L, Lederer WJ, Sesaki H et al. Transient assembly of f-actin on the outer mitochondrial membrane contributes to mitochondrial fission. J Cell Biol 2015; 208: 109–123.
Simon VR, Karmon SL, Pon LA . Mitochondrial inheritance: cell cycle and actin cable dependence of polarized mitochondrial movements in Saccharomyces cerevisiae. Cell Motil Cytoskeleton 1997; 37: 199–210.
Fehrenbacher KL, Boldogh IR, Pon LA . A role for Jsn1p in recruiting the Arp2/3 complex to mitochondria in budding yeast. Mol Biol Cell 2005; 16: 5094–5102.
Boldogh IR, Yang HC, Nowakowski WD, Karmon SL, Hays LG, Yates JR et al. Arp2/3 complex and actin dynamics are required for actin-based mitochondrial motility in yeast. Proc Natl Acad Sci USA 2001; 98: 3162–3167.
Xu Y, Lu S . Transforming growth factor-β1-induced epithelial to mesenchymal transition increases mitochondrial content in the A549 non-small cell lung cancer cell line. Mol Med Rep 2015; 11: 417–421.
Gomes LC, Scorrano L . Mitochondrial morphology in mitophagy and macroautophagy. Biochim Biophys Acta 2013; 1833: 205–212.
Twig G, Elorza A, Molina AJ, Mohamed H, Wikstrom JD, Walzer G et al. Fission and selective fusion govern mitochondrial segregation and elimination by autophagy. EMBO J 2008; 27: 433–446.
Kanki T, Klionsky DJ . The molecular mechanism of mitochondria autophagy in yeast. Mol Microbiol 2010; 75: 795–800.
Gomes LC, Benedetto GD, Scorrano L . During autophagy mitochondria elongate, are spared from degradation and sustain cell viability. Nat Cell Biol 2011; 13: 589–598.
Rambold AS, Kostelecky B, Elia N, Lippincott-Schwartz J . Tubular network formation protects mitochondria from autophagosomal degradation during nutrient starvation. Proc Natl Acad Sci USA 2011; 108: 10190–10195.
Arnoult D, Rismanchi N, Grodet A, Roberts RG, Seeburg DP, Estaquier J et al. Bax/Bak-dependent release of DDP/TIMM8a promotes Drp1-mediated mitochondrial fission and mitoptosis during programmed cell death. Curr Biol 2005; 15: 2112–2118.
Nowikovsky K, Reipert S, Devenish RJ, Schweyen RJ . Mdm38 protein depletion causes loss of mitochondrial K+/H+ exchange activity, osmotic swelling and mitophagy. Cell Death Differ 2007; 14: 1647–1656.
Gomes LC, Di Benedetto G, Scorrano L . During autophagy mitochondria elongate, are spared from degradation and sustain cell viability. Nat Cell Biol 2011; 13: 589–598.
Kanki T, Wang K, Baba M, Bartholomew CR, Lynch-Day MA, Du Z et al. A genomic screen for yeast mutants defective in selective mitochondria autophagy. Mol Biol Cell 2009; 20: 4730–4738.
Rambold AS, Kostelecky B, Elia N, Lippincott-Schwartz J . Tubular network formation protects mitochondria from autophagosomal degradation during nutrient starvation. Proc Natl Acad Sci USA 2011; 108: 10190–10195.
Caino MC, Chae YC, Vaira V, Ferrero S, Nosotti M, Martin NM et al. Metabolic stress regulates cytoskeletal dynamics and metastasis of cancer cells. J Clin Invest 2013; 123: 2907–2920.
Maes H, Van Eygen S, Krysko DV, Vandenabeele P, Nys K, Rillaerts K et al. BNIP3 supports melanoma cell migration and vasculogenic mimicry by orchestrating the actin cytoskeleton. Cell Death Dis 2014; 5: e1127.
Acknowledgements
AC is supported by Associazione Italiana Ricerca sul Cancro (AIRC, IG15862) and by Italian Ministry of Health (GR-2011-02350937). We wish to thank medical illustrator Antonia Conti for her precious help in the graphical realization of the figures.
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Gugnoni, M., Sancisi, V., Manzotti, G. et al. Autophagy and epithelial–mesenchymal transition: an intricate interplay in cancer. Cell Death Dis 7, e2520 (2016). https://doi.org/10.1038/cddis.2016.415
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DOI: https://doi.org/10.1038/cddis.2016.415